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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Magnetic Resonance Elastography for Measuring the Compliance of Chronic Total Occlusions

Kates, Brian S. 12 December 2011 (has links)
Percutaneous coronary revascularization of chronic total occlusions (CTOs) is difficult due to the presence of a hard proximal fibrous cap and lack of image guidance. The use of x-ray fluoroscopy alone makes it difficult to identify vessel boundaries and occlusive constituents which would aid the process of revascularization. It also can be difficult to keep a guidewire intraluminal without puncturing the vessel wall. Although several imaging modalities are being developed, a technique for measuring the stiffness of occlusions would facilitate revascularization by helping the process of guidewire selection and placement. In this study, a technique known as static magnetic resonance elastography is explored as a method of determining the compliance of CTOs. A finite element simulation was used to determine the response of an artery to deformation, and displacement images were obtained from an artery phantom using a stimulated echo MR imaging pulse sequence and a pneumatic compression system.
22

Magnetic Resonance Elastography for Measuring the Compliance of Chronic Total Occlusions

Kates, Brian S. 12 December 2011 (has links)
Percutaneous coronary revascularization of chronic total occlusions (CTOs) is difficult due to the presence of a hard proximal fibrous cap and lack of image guidance. The use of x-ray fluoroscopy alone makes it difficult to identify vessel boundaries and occlusive constituents which would aid the process of revascularization. It also can be difficult to keep a guidewire intraluminal without puncturing the vessel wall. Although several imaging modalities are being developed, a technique for measuring the stiffness of occlusions would facilitate revascularization by helping the process of guidewire selection and placement. In this study, a technique known as static magnetic resonance elastography is explored as a method of determining the compliance of CTOs. A finite element simulation was used to determine the response of an artery to deformation, and displacement images were obtained from an artery phantom using a stimulated echo MR imaging pulse sequence and a pneumatic compression system.
23

Application of magnetic resonance elastography to atherosclerosis

Thomas-Seale, Lauren Elizabeth Jane January 2015 (has links)
Atherosclerosis is the root cause of a wide range of cardiovascular diseases. Although it is a global arterial disease, some of the most severe consequences, heart attack and stroke, are caused by ischemia due to local plaque rupture. The risk of rupture is related to the mechanical properties of the plaque. Magnetic resonance elastography (MRE) images tissue elasticity by inverting, externally excited, harmonic wave displacement into a stiffness map, known as an elastogram. The aim of this thesis is to computationally and experimentally investigate the application of MRE to image the mechanical properties of atherosclerotic plaques. The cardiac cycle, lumen boundary, size and inhomogeneous nature of atherosclerotic plaques pose additional complications compared to more well-established MRE applications. Computational modelling allowed these complications to be assessed in a controlled and simplified environment, prior to experimental studies. Computational simulation of MRE was proposed by combining steady state shear waves, yielded by finite element analysis, with the 2D Helmholtz inversion algorithm. The accuracy and robustness of this technique was ascertained through models of homogeneous tissue. A computational sensitivity study was conducted through idealised atherosclerotic plaques, incorporating the effects of disease variables and mechanical, imaging and inversion parameters on the wave images and elastograms. Subject to parameter optimisation, a change in local plaque shear modulus with composition was established. Amongst other variables, an increase of the lipid pool volume in 10mm3 increments was shown to decrease the predicted shear modulus for stenosis sizes between 50% and 80%. The limitations of the Helmholtz inversion algorithm were demonstrated. A series of arterial phantoms containing plaques of various size and stiffness were developed to test the experimental feasibility of the technique. The lumen was identifiable in the wave images and elastograms. However the experimental wave propagation, noise and resolution left the vessel wall and plaque unresolvable. A computational replica of the phantoms yielded clearer wave images and elastograms, indicating that changes to the experimental procedure could lead to more successful results. The comparison also highlighted certain areas for improvement in the computational work. Imaging protocol for in vivo MRE through the peripheral arteries of healthy volunteers and peripheral artery disease patients was developed. The presence of physiological motion and low signal to noise ratios made the vessel anatomy unidentifiable. The application of MRE to atherosclerotic plaques through simulations, arterial phantoms, healthy volunteers and patients has shown that although there is the potential to identify a change in shear modulus with composition, the addition of realistic experimental complications are severely limiting to the technique. The gradual addition of complications throughout the thesis has allowed their impact to be assessed and in turn has highlighted areas for future research.
24

An Image Based Vibration Sensor for Soft Tissue Modal Analysis in a Digital Image Elasto Tomography (DIET) System

Feng, Sheng January 2011 (has links)
Digital Image Elasto Tomography (DIET) is a non-invasive elastographic breast cancer screening technology, relying on image-based measurement of surface vibrations induced on a breast by mechanical actuation. Knowledge of frequency response characteristics of a breast prior to imaging is critical to maximize the imaging signal and diagnostic capability of the system. A non-invasive image based modal analysis system that is designed to be able to robustly and rapidly identify resonant frequencies in soft tissue is presented in this thesis. A feasibility analysis reveals that three images per oscillation cycle are sufficient to capture the relative motion behavior at a given frequency. Moreover, the analysis suggests that 2D motion analysis is able to give an accurate estimation of the response at a particular frequency. Thus, a sweep over critical frequency ranges can be performed prior to imaging to determine critical imaging settings of the DIET system to maximize diagnositc performance. Based on feasibility simulations, a modal analysis system is presented that is based on the existing DIET digital imaging system. A frequency spectrum plot that comprises responses gathered from more than 30 different frequencies can be obtained in about 6 minutes. Preliminary results obtained from both phantom and human trials indicate that distinctive resonant frequencies can be obtained with the modal analysis system. Due to inhomogeneous properties of human breast tissues, different imaging location appear to pick up different resonances. However, there has been very limited clinical data for validating such behavior. Overall, a modal analysis system for soft tissue has been developed in this thesis. The system was first evaluated in simulation, then implemented in hardware and software, and finally successfully validated in silicone phantoms as well as human breasts.
25

A preliminary study into non invasive breast cancer diagnosis using magnetic resonance elastography.

Viviers, David January 2014 (has links)
Attenuation and damping in elastography are naturally of great interest as the presence of these effects in biological tissue goes without question and therefore must be addressed if quantitative assessment of tissue elastic properties is to be achieved. Additionally, given the change in the tissue structure present in the diseases that elastographic imaging seeks to detect and diagnose, there is every reason to expect that the resulting lesions will also exhibit a change in their attenuation behaviour, indicating diagnostic value to any description of the damping property distribution elastographic methods are able to provide. This thesis will present the unique contribution of the development of several Elastographic models for MR based reconstructions of soft tissue. A method for the reconstruction of both Viscoelastic and Rayleigh damping based damped elastic properties has been developed for use with MR detected time-harmonic motion data and has been shown to lead to reasonable results in both homogeneous and heterogeneous phantoms of varying material types. A poro-elastic modelling is thought to provide a more accurate description of tissue structure by accounting for, in part, the complex interactions between the solid and fluid phases present in vivo. The foundation for a poro-elastic material behaviour will be explored and presented to support the premise. A meaningful mapping of the orthotropic shear moduli distributions in three directions has demonstrated enough evidence that the orthotropic MRE can be a feasible technique to determine orthotropic elasticity parameters of a biological tissue, noninvasively. The orthotropic achievements throughout this project can be useful for future clinical cancer diagnostics by augmenting the information obtained from the orthotropic MRE reconstructions between normal tissue and tumours.
26

Micro-motion detection by optical coherence tomography (OCT) and its clinical applications

Guan, Guangying January 2015 (has links)
Detection of micro-motion on biological tissues has various applications such as ultrasound elastography and magnetic resonance elastography (MRE). Ultrasound transducers, the most commonly used tool to detect endogenous and exogenous micro-motions, have a number of drawbacks: including the requirements of the physical contact with the sample and limited spatial resolution (millimetre scale). The aim of this thesis is to develop a non-contact phase-sensitive imaging technique which is suitable for functional imaging in the micron range which also has the potential for quantitative analysis of relative properties resulting from an appropriate image processing. Concerning imaging techniques, this thesis focused on optical coherence tomography (OCT) and in particular on phase-sensitive optical coherence tomography (PhS-OCT). In this thesis, a PhS-OCT system is developed for micro-motion detection and a dual camera PhS-OCT system is developed to double the imaging acquiring speed and improve the sensitivity to small phase change. Two applications of PhS-OCT combining micro-motions detection are preformed: 1) Photo-thermal OCT (PT-OCT) system is developed to detect the photo-thermal phenomenon of nanoparticles. A mathematic model is proposed to analyse and reconstruct the distribution of nanoparticles in biological tissues. 2) A quantitative 3D optical coherence elastography (OCE) system and algorithm are developed to analysis the mechanical property of tissue. A feasibility study is carried for the diagnosis of prostate cancer (PCa) using this technique. Results show that PhS-OCT is a powerful tool for the detection of micro-motions (micron range). Functional OCT based on it such as PT-OCT and OCE offers potential in diagnostic and therapeutic in clinical applications, e.g. PT-OCT can be used to detect and map the distribution and concentration of dye and drug in tissues or organs. 3D OCE can provide useful information for early localization and diagnosis of cancer.
27

Evaluation of harmonic motion elastography and acousto-optic imaging for monitoring lesion formation by high intensity focused ultrasound

Draudt, Andrew Bruce January 2012 (has links)
Malignant or benign tumors may be ablated with high‐intensity focused ultrasound (HIFU). This technique, known as focused ultrasound surgery (FUS), has been actively investigated for decades, but slow to be implemented and difficult to control due to lack of real‐time feedback during ablation. Two methods of imaging and monitoring HIFU lesions during formation were implemented simultaneously, in order to investigate the efficacy of each and to increase confidence in the detection of the lesion. The first, Acousto‐Optic Imaging (AOI) detects the increasing optical absorption and scattering in the lesion. The intensity of a diffuse optical field in illuminated tissue is mapped at the spatial resolution of an ultrasound focal spot, using the acousto‐optic effect. The second, Harmonic Motion Imaging (HMI), detects the changing stiffness in the lesion. The HIFU beam is modulated to force oscillatory motion in the tissue, and the amplitude of this motion, measured by ultrasound pulse‐echo techniques, is influenced by the stiffness. Experiments were performed on store‐bought chicken breast and freshly slaughtered bovine liver. The AOI results correlated with the onset and relative size of forming lesions much better than prior knowledge of the HIFU power and duration. For HMI, a significant artifact was discovered due to acoustic nonlinearity. The artifact was mitigated by adjusting the phase of the HIFU and imaging pulses. A more detailed model of the HMI process than previously published was made using finite element analysis. The model showed that the amplitude of harmonic motion was primarily affected by increases in acoustic attenuation and stiffness as the lesion formed and the interaction of these effects was complex and often counteracted each other. Further biological variability in tissue properties meant that changes in motion were masked by sample‐to‐sample variation. The HMI experiments predicted lesion formation in only about a quarter of the lesions made. In simultaneous AOI/HMI experiments it appeared that AOI was a more robust method for lesion detection. / Bernard M. Gordon Center for Subsurface and Imaging Systems (CenSSIS) via the NSF ERC award number EEC‐9986821.
28

Assessment of Mechanical and Hemodynamic Vascular Properties using Radiation-Force Driven Methods

Dumont, Douglas M. January 2011 (has links)
<p>Several groups have proposed classifying atherosclerotic disease by using acoustic radiation</p><p>force (ARF) elasticity methods to estimate the mechanical and material</p><p>properties of plaque. However, recent evidence suggests that cardiovascular disease</p><p>(CVD), in addition to involving pathological changes in arterial tissue, is also a</p><p>hemodynamic remodeling problem. As a result, integrating techniques that can</p><p>estimate localized hemodynamics relevant to CVD remodeling with existing ARF based</p><p>elastography methods may provide a more complete assessment of CVD.</p><p>This thesis describes novel imaging approaches for combining clinically-accepted,</p><p>ultrasound-based flow velocity estimation techniques (color-flow Doppler and spectral-</p><p>Doppler imaging) with ARF-based elasticity characterization of vascular tissue. Techniques</p><p>for integrating B-mode, color-flow Doppler, and ARFI imaging were developed</p><p>(BACD imaging), validated in tissue-mimicking phantoms, and demonstrated for in</p><p>vivo imaging. The resulting system allows for the real-time acquisition (< 20 Hz) of</p><p>spatially registered B-mode, flow-velocity, and ARFI displacement images of arterial</p><p>tissue throughout the cardiac cycle. ARFI and color-flow Doppler imaging quality,</p><p>transducer surface heating, and tissue heating were quantified for different frame-rate</p><p>and scan-duration configurations. The results suggest that BACD images can be acquired</p><p>at high frame rates with minimal loss of imaging quality for approximately</p><p>five seconds, while staying beneath suggested limits for tissue and transducer surface</p><p>heating.</p><p>Because plaque-burden is potentially a 3D problem, techniques were developed</p><p>to allow for the 3D acquisition of color-flow Doppler and ARFI displacement data</p><p>using a stage-controlled, freehand scanning approach. The results suggest that a</p><p>40mm x 20mm x 25mm BACD volume can be acquired in approximately three seconds.</p><p>Jitter, SNR, lesion CNR, soft-plaque detectability, and flow-area assessment were</p><p>quantified in tissue mimicking phantoms with a range of elastic moduli relevant</p><p>to ARFI imaging applications. Results suggest that both jitter and SNR degrade</p><p>with increased sweep velocity, and that degradation is worse when imaging stiffer</p><p>materials. The results also suggest that a transition between shearing-dominated</p><p>jitter and motion-dominated jitter occurs sooner with faster sweep speeds and in</p><p>stiffer materials. These artifacts can be reduced with simple, linear filters. Results</p><p>from plaque mimicking phantoms suggest that the estimation of soft-plaque area</p><p>and flow area, both important tasks for CVD imaging, are only minimally affected</p><p>at faster sweep velocities.</p><p>Current clinical assessment of CVD is guided by spectral Doppler velocity methods.</p><p>As a result, novel imaging approaches (SAD-SWEI, SAD-GATED) were developed</p><p>for combining spectral Doppler methods with existing ARF-based imaging</p><p>techniques to allow for the combined assessment of cross-luminal velocity profiles,</p><p>wall-shear rate (WSR), ARFI displacement and ARF-induced wave velocities. These</p><p>techniques were validated in controlled phantom experiments, and show good agreement</p><p>between previously described ARF-techniques and theory. Initial in vivo feasibility</p><p>was then evaluated in five human volunteers. Results show that a cyclic</p><p>variability in both ARFI displacement and ARF-generated wave velocity occurs during</p><p>the cardiac cycle. Estimates of WSR and peak velocity show good agreement</p><p>with previous ultrasonic-based assessments of these metrics. In vivo ARFI and Bmode/</p><p>WSR images of the carotid vasculature were successfully formed using ECG gating</p><p>techniques.</p><p>This thesis demonstrates the potential of these methods for the combined assessment</p><p>of vascular hemodynamics and elasticity. However, continued investigation</p><p>into optimizing sequences to reduce transducer surface heating, removing the angle</p><p>dependency of the SAD-SWEI/SAD-GATED methods, and decreasing processing</p><p>time will help improve the clinical viability of the proposed imaging techniques.</p> / Dissertation
29

Performance Analysis of a New Ultrasound Axial Strain Time Constant Estimation

Nair, Sanjay P. 2010 May 1900 (has links)
New elastographic techniques such as poroelastography and viscoelasticity imaging aim at imaging the temporal mechanical behavior of tissues. These techniques usually involve the use of curve fitting methods as applied to noisy data to estimate new elastographic parameters. As of today, however, image quality performance of these new elastographic imaging techniques is still largely unknown due to a paucity of data and the lack of systematic studies that analyze performance limitations of estimators suitable for these novel applications. Furthermore, current elastographic implementations of poroelasticity and viscoelasticity imaging methods are in general too slow and not optimized for clinical applications. In this paper, we propose a new elastographic time constant (TC) estimator, which is based on the use of the Least Square Error (LSE) curve-fitting method and the Levenberg-Marquardt (LM) optimization rule as applied to noisy elastographic data obtained from a tissue under creep compression. The estimator's performance is analyzed using simulations and quantified in terms of accuracy, precision, sensitivity, signal-to-noise ratio (SNR) and speed. Experiments are performed as a proof of principle of the technical applicability of the new estimator on real experimental data. The results of this study demonstrate that the new elastographic estimator described in this thesis can produce highly accurate, sensitive and precise time constant estimates in real-time and at high SNR. In the future, the use of this estimator could allow real-time imaging of the temporal behavior of complex tissues and provide advances in lymphedema and cancer imaging.
30

High Frequency Shear Wave Imaging: A Feasibility Study In Tissue Mimicking Gelatin Phantoms

Maeva, Anna 18 March 2014 (has links)
Shear wave (SW) imaging is an ultrasound elastogrpahy technique for estimating the elastic properties of biological tissues. Increasing the frequency would improve both the confinement of the radiation force generating the shear wave, and the imaging spatial resolution. The objectives of the study were to realize a simple high frequency (HF) system for the generation and detection of SW propagation and to implement this system to develop and characterize tissue-mimicking gelatin phantoms (TMGP) for HF SWI with elastic properties in the range of those encountered in biological tissue. A 5 MHz and 10 MHz focused transducer were used to induced SW’s in TMGP ranging from 4% to 12% gelatin with 3% silica for scattering and a 25 MHz single-element focused transducer recorded pulse-echo signals in order to capture the SW. The shear wave speeds in the TMGP were found to range linearly from 1.59-4.59 m/s in the 4% to 12% gelatin samples.

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